Aya Miyabe

Bio: Aya Miyabe is an academic researcher from Kobe University. The author has contributed to research in topics: Cas9 & Genome editing. The author has an hindex of 1, co-authored 1 publications receiving 731 citations.

Targeted nucleotide editing using hybrid prokaryotic and vertebrate adaptive immune systems

Abstract: INTRODUCTION To combat invading pathogens, cells develop an adaptive immune response by changing their own genetic information. In vertebrates, the generation of genetic variation (somatic hypermutation) is an essential process for diversification and affinity maturation of antibodies that function to detect and sequester various foreign biomolecules. The activation-induced cytidine deaminase (AID) carries out hypermutation by modifying deoxycytidine bases in the variable region of the immunoglobulin locus that produces antibody. AID-generated deoxyuridine in DNA is mutagenic as it can be miss-recognized as deoxythymine, resulting in C to T mutations. CRISPR (clustered regularly interspaced short palindromic repeats)/Cas (CRISPR-associated) is a prokaryotic adaptive immune system that records and degrades invasive foreign DNA or RNA. The CRISPR/Cas system cleaves and incorporates foreign DNA/RNA segments into the genomic region called the CRISPR array. The CRISPR array is transcribed to produce crispr-RNA that serves as guide RNA (gRNA) for recognition of the complementary foreign DNA/RNA in a ribonucleoprotein complex with Cas proteins, which degrade the target. The CRISPR/Cas system has been repurposed as a powerful genome editing tool, because it can be programmed to cleave specific DNA sequence by providing custom gRNAs. RATIONALE Although the precise mechanism by which AID specifically mutates the immunoglobulin locus remains elusive, targeting of AID activity is facilitated by the formation of a single-stranded DNA region, such as a transcriptional RNA/DNA hybrid (R-loop). The CRISPR/Cas system can be engineered to be nuclease-inactive. The nuclease-inactive form is capable of unfolding the DNA double strand in a protospacer adjacent motif (PAM) sequence-dependent manner so that the gRNA binds to complementary target DNA strand and forms an R-loop. The nuclease-deficient CRISPR/Cas system may serve as a suitable DNA-targeting module for AID to catalyze site-specific mutagenesis. RESULTS To determine whether AID activity can be specifically targeted by the CRISPR/Cas system, we combined dCas9 (a nuclease-deficient mutant of Cas9) from Streptococcus pyogenes and an AID ortholog, PmCDA1 from sea lamprey, to form a synthetic complex (Target-AID) by either engineering a fusion between the two proteins or attaching a SH3 (Src 3 homology) domain to the C terminus of dCas9 and a SHL (SH3 interaction ligand) to the C terminus of PmCDA1. Both of these complexes performed highly efficient site-directed mutagenesis. The mutational spectrum was analyzed in yeast and demonstrated that point mutations were dominantly induced at cytosines within the range of three to five bases surrounding the –18 position upstream of the PAM sequence on the noncomplementary strand to gRNA. The toxicity associated with the nuclease-based CRISPR/Cas9 system was greatly reduced in the Target-AID complexes. Combination of PmCDA1 with the nickase Cas9(D10A) mutant, which retains cleavage activity for noncomplementary single-stranded DNA, was more efficient in yeast but also induced deletions as well as point mutations in mammalian cells. Addition of the uracil DNA glycosylase inhibitor protein, which blocks the initial step of the uracil base excision repair pathway, suppressed collateral deletions and further improved targeting efficiency. Potential off-target effects were assessed by whole-genome sequencing of yeast as well as deep sequencing of mammalian cells for regions that contain mismatched target sequences. These results showed that off-target effects were comparable to those of conventional CRISPR/Cas systems, with a reduced risk of indel formation. CONCLUSION By expanding the genome editing potential of the CRISPR/Cas9 system by deaminase-mediated hypermutation, Target-AID demonstrated a very narrow range of targeted nucleotide substitution without the use of template DNA. Nickase Cas9 and uracil DNA glycosylase inhibitor protein can be used to boost the targeting efficiency. The reduced cytotoxicity will be beneficial for use in cells that are sensitive to artificial nucleases. Use of other types of nucleotide-modifying enzymes and/or other CRISPR-related systems with different PAM requirements will expand our genome-editing repertoire and capacity.

Programmable base editing of A•T to G•C in genomic DNA without DNA cleavage

Abstract: The spontaneous deamination of cytosine is a major source of transitions from C•G to T•A base pairs, which account for half of known pathogenic point mutations in humans. The ability to efficiently convert targeted A•T base pairs to G•C could therefore advance the study and treatment of genetic diseases. The deamination of adenine yields inosine, which is treated as guanine by polymerases, but no enzymes are known to deaminate adenine in DNA. Here we describe adenine base editors (ABEs) that mediate the conversion of A•T to G•C in genomic DNA. We evolved a transfer RNA adenosine deaminase to operate on DNA when fused to a catalytically impaired CRISPR-Cas9 mutant. Extensive directed evolution and protein engineering resulted in seventh-generation ABEs that convert targeted A•T base pairs efficiently to G•C (approximately 50% efficiency in human cells) with high product purity (typically at least 99.9%) and low rates of indels (typically no more than 0.1%). ABEs introduce point mutations more efficiently and cleanly, and with less off-target genome modification, than a current Cas9 nuclease-based method, and can install disease-correcting or disease-suppressing mutations in human cells. Together with previous base editors, ABEs enable the direct, programmable introduction of all four transition mutations without double-stranded DNA cleavage.

RNA editing with CRISPR-Cas13

Abstract: Nucleic acid editing holds promise for treating genetic disease, particularly at the RNA level, where disease-relevant sequences can be rescued to yield functional protein products. Type VI CRISPR-Cas systems contain the programmable single-effector RNA-guided ribonuclease Cas13. We profiled type VI systems in order to engineer a Cas13 ortholog capable of robust knockdown and demonstrated RNA editing by using catalytically inactive Cas13 (dCas13) to direct adenosine-to-inosine deaminase activity by ADAR2 (adenosine deaminase acting on RNA type 2) to transcripts in mammalian cells. This system, referred to as RNA Editing for Programmable A to I Replacement (REPAIR), which has no strict sequence constraints, can be used to edit full-length transcripts containing pathogenic mutations. We further engineered this system to create a high-specificity variant and minimized the system to facilitate viral delivery. REPAIR presents a promising RNA-editing platform with broad applicability for research, therapeutics, and biotechnology.

The CRISPR tool kit for genome editing and beyond.

Abstract: CRISPR is becoming an indispensable tool in biological research. Once known as the bacterial immune system against invading viruses, the programmable capacity of the Cas9 enzyme is now revolutionizing diverse fields of medical research, biotechnology, and agriculture. CRISPR-Cas9 is no longer just a gene-editing tool; the application areas of catalytically impaired inactive Cas9, including gene regulation, epigenetic editing, chromatin engineering, and imaging, now exceed the gene-editing functionality of WT Cas9. Here, we will present a brief history of gene-editing tools and describe the wide range of CRISPR-based genome-targeting tools. We will conclude with future directions and the broader impact of CRISPR technologies.

Genome editing with CRISPR–Cas nucleases, base editors, transposases and prime editors

Abstract: The development of new CRISPR-Cas genome editing tools continues to drive major advances in the life sciences. Four classes of CRISPR-Cas-derived genome editing agents-nucleases, base editors, transposases/recombinases and prime editors-are currently available for modifying genomes in experimental systems. Some of these agents have also moved rapidly into the clinic. Each tool comes with its own capabilities and limitations, and major efforts have broadened their editing capabilities, expanded their targeting scope and improved editing specificity. We analyze key considerations when choosing genome editing agents and identify opportunities for future improvements and applications in basic research and therapeutics.

Base editing: precision chemistry on the genome and transcriptome of living cells

Abstract: RNA-guided programmable nucleases from CRISPR systems generate precise breaks in DNA or RNA at specified positions. In cells, this activity can lead to changes in DNA sequence or RNA transcript abundance. Base editing is a newer genome-editing approach that uses components from CRISPR systems together with other enzymes to directly install point mutations into cellular DNA or RNA without making double-stranded DNA breaks. DNA base editors comprise a catalytically disabled nuclease fused to a nucleobase deaminase enzyme and, in some cases, a DNA glycosylase inhibitor. RNA base editors achieve analogous changes using components that target RNA. Base editors directly convert one base or base pair into another, enabling the efficient installation of point mutations in non-dividing cells without generating excess undesired editing by-products. In this Review, we summarize base-editing strategies to generate specific and precise point mutations in genomic DNA and RNA, highlight recent developments that expand the scope, specificity, precision and in vivo delivery of base editors and discuss limitations and future directions of base editing for research and therapeutic applications.